lecture 3: The greenhouse effect
Concepts from Lecture 2 Temperature Scales Forms of Heat Transfer Electromagnetic Spectrum Planck Law Stefan-Boltzmann Law Inverse Square Law Reflectivity or Albedo Solar (Shortwave) and Terrestrial (Longwave) Radiation
Source: OSTP
Strong Evidence for Global Warming 1928 2000 From US Climate Change Science Program South Cascade Glacier, Washington
Global mean surface temperature change based on surface air measurements over land and SSTs over ocean. Source: Update of Hansen et al., JGR, 106, 23947, 2001; Reynolds and Smith, J. Climate, 7, 1994;Rayner et al., JGR, 108, 2003 (afterjames E.Hansen 2006).
Climate forcing agents in the industrial era. Effective forcing accounts for efficacy of the forcing mechanism Source: Hansen et al., JGR, 110, D18104, 2005.
The greenhouse effect of Venus From geometry, we can calculate the average solar flux over the surface of Venus. It is approximately 661 W/m 2. Venus is very reflective of solar radiation. In fact, it has a reflectivity (or albedo) of 0.8, so the planet absorbs approximately 661 X 0.2 = 132 W/m 2. By assuming that the incoming radiation equals the outgoing radiation (energy balance), we can convert this into an effective radiating temperature by invoking the Stefan-Boltzmann law (total energy = σt 4 ). We find that T=220 K. But Venus surface has a temperature of 730 K!!! The explanation for this huge discrepancy is the planet s greenhouse effect.
The greenhouse effect of Earth From geometry, we can calculate the average solar flux at the top of the atmosphere. It is approximately 343 W/m 2. The earth has a much lower albedo than Venus (0.3), so the planet absorbs approximately 343 X 0.7 = 240 W/m 2. By assuming that the incoming radiation equals the outgoing radiation, we can convert this into an effective radiating temperature by invoking the Stefan-Boltzmann law (total energy = σt 4 ). We find that T=254 K. Earth s surface has a temperature of 288 K While much smaller than Venus greenhouse effect, Earth s is crucial for the planet s habitability. Without the greenhouse effect, the temperature today in Los Angeles would be about 0 degrees Fahrenheit.
Main Constituents of the Earth s Atmosphere Nitrogen 78% Oxygen 21% Argon 1% Water Vapor 0-4% Carbon Dioxide 0.037% (increasing) Nitrogen, Oxygen, and Argon hardly interact with radiation. On the other hand water vapor and carbon dioxide both interact with infrared radiation---the type emitted by the Earth and its atmosphere.
A greenhouse gas is defined as a gas that absorbs significantly the radiation emitted by the Earth and its atmosphere (Infrared, IR, or longwave radiation). Important Greenhouse Gases (concentrations in parts per million volume) water vapor 0.1-40,000 carbon dioxide 370 methane 1.7 nitrous oxide 0.3 ozone 0.01 chlorofluorocarbons ~0.0007
Greenhouse Gases (part 1) Carbon dioxide (CO 2 ): ~0.4%/yr, fossil fuel combustion, photosynthesis, and ocean, ~380 ppmv, present value Water vapor (H 2 O): via temperature feedback Ozone (O 3 ): in the troposphere (~10 %)
Greenhouse Gases (related to O 3 ) Methane (CH 4 ): increasing human and animal populations, and change in land use (~ 1 2%/yr, ~1.7 ppmv) CH 4 + 4O 2 CH 2 O + H 2 O + 2O 3 (OH, NO) Nitrous Oxide (N 2 O): Fossil fuel combustion and fertilizer denitrification (~ 0.2%/yr) Tropophere (NO x = NO, NO 2, ~ O 3 ) Chlorofluorocarbons (CFCs): aerosol spray cans & refrigerant (Montreal Protocol, 1987) Cl + O 3 ClO + O 2 ClO + O Cl + O 2
Why do certain gases interact with radiation? When radiation impinges on a molecule, it can excite the molecule, either by vibrating (vibrational energy) or rotating (rotational energy) it. Molecules of a particular kind of gas have a different shape from molecules of another type of gas, and so are excited by radiation in different ways. CH 4 H 2 O CO 2
Because of their varying geometries and sizes, different molecules absorb radiation of different wavelengths. For example, CO 2 tends to absorb radiation of a wavelength of 15 μm (this wavelength excites bending vibration of the CO 2 molecule), whereas H 2 O tends to absorb at wavelengths around 16-20 μm (rotation of the H 2 O molecule). CH 4 H 2 O CO 2
Molecules with more than two atoms tend to absorb radiation more effectively than diatomic molecules such as N 2 and O 2. This is because of the net balance of their electron configuration. That is why diatomic nitrogen and oxygen are not greenhouse gases. CH 4 N 2, O 2 H 2 O CO 2
lecture 4: The greenhouse effect (cont.)
Source: OSTP
A greenhouse gas is defined as a gas that absorbs significantly the radiation emitted by the Earth and its atmosphere (Infrared, IR, or longwave radiation). Important Greenhouse Gases (concentrations in parts per million volume) water vapor 0.1-40,000 carbon dioxide 370 methane 1.7 nitrous oxide 0.3 ozone 0.01 chlorofluorocarbons ~0.0007
CO 2 greenhouse warming Fig. 3.3 Vibrational modes of diatomic and triatomic atmospheric molecules and the axes of rotational freedom for linear and symmetrical top molecules.
Energies of a Molecule O----C----O Translational energy: continuous motion (~temperature) Vibrational energy Rotational energy Electronic energy (related to electrons, O 3 ) Discrete energy levels (CO 2 ) Energy 4 Absorption Nothing in between Nothing in between Nothing in between Energy 3 Energy 2 Energy 1
UV (.1-.4 μm) Visible (.4-.7 μm) Thermal Infrared ( >5 μm) Interaction of the atmosphere with radiation I I I I I I I I I I I I I I I I
Note that the separation between the solar and terrestrial spectra occurs at about 5 μm
So how does this create a greenhouse effect? The greenhouse effect occurs because the atmosphere is relatively transparent to the wavelengths of solar radiation, while it absorbs infrared radiation. So a large chunk of the sun s radiation makes it to the earth s surface. At the same time, the atmosphere containing greenhouse gases absorbs the radiation emitted by the earth s surface, and re-emits it back to the surface, increasing the total energy the surface receives. This forces the earth s surface to become warmer than it would be otherwise.
The greenhouse effect is a naturallyoccurring phenomenon on the earth as it is on Venus. The enhancement of this effect by increasing greenhouse gases associated with man-made activities is the reason for concern about climate change.
Greenhouse Gases (part 1) Carbon dioxide (CO 2 ): ~0.4%/yr, fossil fuel combustion, photosynthesis, and ocean, ~380 ppmv, present value Water vapor (H 2 O): via temperature feedback Ozone (O 3 ): in the troposphere (~10 %)
Increase of CO 2 (Fossil fuel combustion) Fig. 8.11 Concentration of atmospheric CO 2 at Mauna Loa Observatory, Hawaii, expressed as a mole fraction in parts per million of dry air for the period 1958-2000 (courtesy of Pieter Tans, Geophysical Monitoring for Climate Change, Environmental Research Laboratory, National Oceanic and Atmospheric Administration). (b) Atmospheric CO 2 concentration for the past 250 years as indicated by measurements in air trapped in ice core from Antarctica determined by Neftel et al. (1985) and extended to the present using the Mauna Loa recorded displayed in (a).
(Warming) Increase of CO 2 will trap more IR radiation Increase of CO 2 won t significantly affect solar radiation
Thermal structure of the atmosphere Increase in Greenhouse Gases Colder Warmer 90% of the atmosphere s mass is in the troposphere.
(After James E. Hansen 2006)
Radiative Equilibrium (for extra credit) Energy Conservation Principle at the top of the atmosphere (TOA) Incoming solar energy absorbed = Outgoing infrared energy emitted where thus S 2 4 2 ( 1 r) π ae = σte 4π ae σ = Stefan-Boltzmann constant S = Solar constant (total solar energy/time/area at TOA) r = Global albedo 0.3 a e = Radius of the Earth T e = Equilibrium temperature of the Earth-atmosphere-system T e = [ S( 1 r) / 4σ ] 1/ 4